KR100743342B1 - A method of manufacturing a semiconductor device - Google Patents

Abstract

When mounting the silicon chip 6A with a narrow pitch of the Au bumps 9 on the module substrate 2, the silicon chip 6A is considered in advance in consideration of the thermal expansion coefficient difference between the silicon chip 6A and the module substrate 2. By making the total pitch of the electrode pad 4a of () narrower than the total pitch of the Au bump 9, the position shift of the Au bump 9 and the electrode pad 4a at the time of heat processing is prevented, and both Secure the contact area.

Description

A manufacturing method of a semiconductor device {A METHOD OF MANUFACTURING A SEMICONDUCTOR DEVICE}

1 is a plan view of a semiconductor device according to one embodiment of the present invention.

2A is a cross-sectional view taken along the line A-A of FIG. 1, and FIG. 2B is a cross-sectional view taken along the line B-B of FIG.

3 is an enlarged cross-sectional view of a main part of FIG. 2A;

4A is a plan view of a main surface of a silicon chip on which an MPU is formed, and FIG. 4B is a cross-sectional view taken along a line C-C in FIG. 4A.

5A is a plan view of the main surface of the silicon chip on which the buffer memory is formed, and FIG. 5B is a sectional view taken along the line D-D in FIG. 5A.

FIG. 6 is a view showing a relative positional relationship between Au bumps disposed along one side of a silicon chip on which an MPU is formed and corresponding electrode pads of a module substrate; FIG.

FIG. 7 is a view showing a relative positional relationship between Au bumps disposed on a silicon chip in which a buffer memory is formed and an electrode pad of a module substrate corresponding thereto. FIG.

8 is a plan view of the main surface of the module substrate, showing the layout of the electrode pads;

9 is a cross-sectional view illustrating a method of manufacturing a semiconductor device according to one embodiment of the present invention.

10 is a cross-sectional view illustrating a method of manufacturing a semiconductor device according to one embodiment of the present invention.                 

11 is a cross-sectional view illustrating a method of manufacturing a semiconductor device according to one embodiment of the present invention.

12 is a cross-sectional view illustrating a method of manufacturing a semiconductor device according to one embodiment of the present invention.

13 is a cross-sectional view illustrating a method of manufacturing a semiconductor device according to one embodiment of the present invention.

14 is a cross-sectional view illustrating a method of manufacturing a semiconductor device according to one embodiment of the present invention.

Fig. 15 is a sectional view of principal parts of a semiconductor device, which is another embodiment of the present invention.

16 is an essential part cross sectional view of a semiconductor device of another embodiment of the present invention;

17 is a plan view of a main surface of a silicon chip in another embodiment of the present invention.

<Explanation of symbols for main parts of drawing>

1: Multichip Module

2: module board

3: wiring

4, 4a, 4b, 5: electrode pads

6A to 6E: Silicon Chip

7: passive element

8, 14: solder bump

9: Au bump                 

10: anisotropic conductive resin

10a, 10b: anisotropic conductive film

11: metal particles

12, 15: wiring board

13: underfill resin (sealing resin)

TECHNICAL FIELD This invention relates to the manufacturing technique of a semiconductor device. Specifically, It is related with the technique effective to apply to the semiconductor device which flip-chip mounts a semiconductor chip to a wiring board via bump electrodes.

Japanese Patent Application Laid-Open No. 11-297759 discloses that the bump electrodes and the electrode terminals are zigzag in order to secure an overlapping area between the bump electrodes and the electrode terminals even when a displacement occurs between the bump electrodes of the chip and the electrode terminals of the substrate. The technique which arrange | positions to and enlarges each area is disclosed.

The present inventors have advanced the development of the multichip module which mounted the many LSI chip on the printed wiring board. In order to realize high density mounting of the LSI chip, the multichip module connects the Au (gold) bump electrode (hereinafter referred to simply as Au bump) formed on the main surface of the chip to the electrode pad (connection terminal) of the wiring board. The flip chip mounting method is adopted. In order to realize high reliability at low cost, a so-called anisotropic conductive film (ACF) in which metal particles such as Ni (nickel) are dispersed in an insulating film made of epoxy resin is interposed between the chip and the wiring board. The electrical connection between the Au bump-electrode pads, the relaxation of thermal stress, and the protection of the connecting portion are simultaneously performed.

In order to mount the chip on the wiring board via the anisotropic conductive film, the anisotropic conductive film cut to the same size as the chip is bonded to the electrode pad of the wiring board, and the chip in which the Au bumps are formed in advance using a wire bonder is anisotropic. It is mounted on a conductive film. Next, the wiring board is heated in the state where the pressure is applied to the chip from the upper side, and the anisotropic conductive film is melted and cured to electrically connect the Au bumps of the chip and the electrode pads of the wiring board through the metal particles in the film. The gap between the chip and the wiring board is sealed with a cured resin.

However, when the heat treatment for melting and curing the anisotropic conductive film is performed, Au bumps are caused by the difference between the thermal expansion coefficient of the wiring board and the chip (3 ppm of silicon chips and about 14 ppm of glass fiber-impregnated epoxy substrates). Position shift occurs between the electrode pad and the electrode pad.

In this case, when the pitch of the electrode pad is relatively wide, the contact area between the bumps and the electrode pads can be secured even if the width of the electrode pad is widened. However, when the pitch of the electrode pad is narrowed due to the multi-terminalization and narrow pitch of the chip, the width of the electrode pad cannot be widened. Therefore, when a position shift occurs between the Au bumps and the electrode pad, the contact area between the two becomes small. Connection reliability is reduced.

As a countermeasure, it is also possible to produce a printed wiring board using a ceramic having a smaller thermal expansion coefficient than that of the resin and to reduce the thermal expansion coefficient difference with the chip, but there is a problem that the manufacturing cost of the substrate is increased.

An object of the present invention is to provide a technique for improving the connection reliability between a chip and a wiring board in a semiconductor device in which the chip is flip-chip mounted on the wiring board via a bump electrode.

An object of the present invention is to provide a technique for connecting a chip and a wiring board with high positioning accuracy in a semiconductor device in which the chip is flip-chip mounted on the wiring board via a bump electrode.

Another object of the present invention is to provide a technique capable of achieving the above object without causing an increase in manufacturing cost.

The above and other objects and novel features of each invention disclosed in accordance with the present specification will become apparent from the description and the accompanying drawings.

Among the inventions disclosed in this specification, an outline of representative ones will be briefly described as follows.

The manufacturing method of the semiconductor device of this invention includes the following processes.

(a) providing a semiconductor chip having a plurality of bump electrodes formed on a main surface thereof,

(b) Process of providing a wiring board in which a plurality of electrode pads are formed on a main surface, and at least a part of the pitch of the plurality of electrode pads is different from the pitch of the plurality of bump electrodes formed on the main surface of the semiconductor chip. ,                         

(c) flip chip mounting on the main surface of the wiring board such that each of the plurality of bump electrodes and each of the plurality of electrode pads are electrically connected.

The manufacturing method of the semiconductor device of this invention is the said process which provides the distance from one end to the other end of the said several electrode pad row formed in the main surface of the said wiring board provided in the said (b) process at the said (a) process. The distance from one end of the plurality of bump electrode rows formed on the main surface of the semiconductor chip to the other end is made smaller.

The manufacturing method of the semiconductor device of this invention includes the following processes.

(a) providing a first and a second semiconductor chip having a plurality of bump electrodes formed on a main surface thereof,

(b) A plurality of electrode pads are formed on the main surface, and at least a part of the pitch of the plurality of electrode pads is different from the pitch of the plurality of bump electrodes formed on the main surface of the first or second semiconductor chip. Providing a substrate,

(c) flip chip mounting the first and second semiconductor chips on a main surface of the wiring board such that each of the plurality of bump electrodes and each of the plurality of electrode pads are electrically connected.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. In addition, in all the drawings for demonstrating an Example, the same code | symbol is attached | subjected to the same member and the repeated description is abbreviate | omitted.

1 is a plan view of a semiconductor device of Example 1, FIG. 2A is a sectional view taken along the line A-A of FIG. 1, and FIG. 2B is a sectional view taken along the line B-B of FIG.

The semiconductor device of this embodiment is a multichip module (MMC) incorporating LSIs such as a high speed microprocessor (MPU), a main memory and a buffer memory.

The module board | substrate 2 of this multichip module 1 is comprised by glass-fiber impregnated epoxy (common name glass epoxy) resin, The inside of this is multi-layer wiring (3) which comprises signal wiring, power wiring, ground wiring, etc. ) Is formed. Moreover, the several electrode pads 4 and 5 electrically connected to the said wiring 3 are formed in the main surface (upper surface) and lower surface of the module substrate 2. The wiring 3 and the electrode pads 4 and 5 are made of Cu (copper), and Ni (nickel) and Au (gold) are plated on the surface of the electrode pads 4 and 5.

On the main surface of the module substrate 2, one silicon chip 6A having an MPU, several silicon chips 6B having a main memory (DRAM), several silicon chips 6C having a buffer memory, several passives The element 7 (capacitor, resistance element), etc. are mounted. A solder bump 8 constituting an external connection terminal for mounting the module substrate 2 on the motherboard or the like is connected to the electrode pad 5 on the lower surface of the module substrate 2.

Each of the silicon chips 6A, 6B, 6C is mounted on the main surface of the module substrate 2 by a flip chip method. That is, each of the silicon chips 6A, 6B, and 6C is electrically connected to the electrode pad 4 of the module substrate 2 via several Au bumps 9 formed on the main surface (element formation surface). On the other hand, the passive element 7 is solder mounted on the main surface of the module substrate 2.

Each of the silicon chips 6A, 6B, and 6C differs in the number and pitch of the Au bumps 9 depending on the type of LSI formed on the main surface thereof. For example, in the silicon chip 6A having the MPU shown in FIG. 2A, the number of terminals 9 (Au bumps) is large (for example, 248 pins), and the pitches of the adjacent Au bumps 9 are narrow. (For example 40 micrometers-50 micrometers). As a result, the electrode pad 4 of the module substrate 2 to which the Au bumps 9 of the silicon chip 6A are connected has a narrow width and a pitch with the adjacent electrode pad 4.

On the other hand, in the silicon chip 6B in which the DRAM is formed, the number of terminals (Au bumps) 9 is small, for example, 74 pins, but since the terminals are arranged in a line at the center of the chip, Au bumps 9 adjacent to each other are formed. ) Is narrowed (for example, 40 µm to 50 µm). As a result, the electrode pad 4 of the module substrate 2 to which the Au bumps 9 of the silicon chip 6B are connected has a narrow width and a pitch with the adjacent electrode pad 4.

On the other hand, the number of terminals of the silicon chip 6C in which the buffer shown in FIG. 2B is formed is 70 pins, for example, and since these are arranged around four sides of the main surface, Au bumps 9 adjacent to each other are provided. ) Is widened (for example, 100 µm to 110 µm). As a result, the electrode pad 4 of the module substrate 2 to which the Au bumps 9 of the silicon chip 6C are connected has a wider width and a pitch with the adjacent electrode pad 4.

Anisotropic conductive resin 10 is filled between each of the silicon chips 6A, 6B, and 6C and the module substrate 2. The anisotropic conductive resin 10 is obtained by dispersing metal particles such as Ni (nickel) in an epoxy-based thermosetting resin. As shown in FIG. 3 and enlarged, each of the silicon chips 6A, 6B and 6C The Au bumps 9 formed on the main surface and the corresponding electrode pads 4 of the module substrate 2 are electrically connected through the metal particles 11 in the anisotropic conductive resin 10. In addition, by filling the anisotropic conductive resin 10 between the silicon chips 6A, 6B, 6C and the module substrate 2, the connection between the Au bumps 9 and the electrode pads 4 is electrically protected and The thermal stress is relieved.

In order to assemble the multichip module 1 configured as described above, first, an active element (silicon chips: 6A, 6B, 6C, etc.) mounted on the module substrate 2 and its main surface and a passive element (7: capacitor, resistor) Device).

In the silicon chips 6A, 6B and 6C, Au bumps 9 are formed in advance by a known wire bonding method using Au wires. 4A is a plan view of the main surface of the silicon chip 6A, and FIG. 4B is a sectional view taken along the line C-C in FIG. 4A. 5A is a plan view of the main surface of the silicon chip 6C, and FIG. 5B is a sectional view taken along the line D-D in FIG. 5A.

The Au bumps 9 are connected on the periphery of the main surface of the silicon chips 6A and 6C, that is, on a bonding pad (not shown) formed outside of the element formation region, in line with each side of the chips 6A and 6C, It is also arranged at the same pitch with each other. The diameter of the Au bumps 9 is about 50 micrometers-55 micrometers, for example. As described above, the Au bumps 9 of the silicon chip 6A are arranged at a narrow pitch of about 40 μm to 50 μm, and the Au bumps 9 of the silicon chip 6C are about 100 μm to 110 μm. It is arranged in a wide pitch. Although not shown, Au bumps 9 are formed on the main surface of the silicon chip 6B on which the main memory (DRAM) is formed in the same manner as described above. The Au bumps 9 of the silicon chip 6B are arranged almost in a line at the center of the main surface of the chip at a narrow pitch of about 40 μm to 50 μm, which is almost the same as the Au bump 9 of the silicon chip 6A. The number of Au bumps is shown abbreviated as compared to the actual.

Here, the relationship between the pitch of the Au bumps 9 formed in the silicon chips 6A, 6B and 6C and the pitch of the electrode pads 4 formed in the module substrate 2 will be described. FIG. 6 is a diagram showing the relative positional relationship between the Au bumps 9 arranged in a line along one side of the silicon chip 6A on which the MPU is formed, and the electrode pads 4a of the module substrate 2 corresponding thereto. .

As shown, the pitch of the Au bumps 9 arranged at one end (left end) of one side of the silicon chip 6A and the Au bumps 9 arranged at the other end (right end) (hereinafter, this pitch is total) Pitch A) is wider than the total pitch B of the two electrode pads 4a and 4a corresponding to each of these two Au bumps 9 and 9 in the room temperature or the temperature range when the semiconductor device is operated. (A> B). In addition, the pitch with the adjacent Au bumps 9 of each of the silicon chips 6A is larger than the pitch of the corresponding electrode pads 4a of the module substrate 2.

Therefore, the amount of deviation (a) between the Au bumps 9 and the electrode pads 4a corresponding thereto corresponds to the Au bumps 9 and the electrode pads 4a corresponding to the Au bumps 9 positioned at the center of one side of the silicon chip 6A. When the amount of deviation with 0 is 0, it becomes as large as the electrode pad 4a at the position away from the electrode pad 4a (O <a ₁ <a ₂ <a ₃ <a ₄ <a ₅ and O <a ' ₁ <a ' ₂ <a' ₃ <a ' ₄ <a' ₅ ). Although not shown, the positional relationship between the Au bumps 9 disposed on the other three sides of the silicon chip 6A and the electrode pads 4a corresponding thereto is also similar to the above.

7 shows the relative positional relationship between the Au bumps 9 arranged in a line along one side of the buffered silicon chip 6C and the electrode pads 4c of the module substrate 2 corresponding thereto. Drawing.

As shown, the total chip C between the Au bumps 9 arranged at one end (left end) of one side of the silicon chip 6C and the Au bumps 9 arranged at the other end (right end) is a combination of these two. It is the same as the total chip D of the two electrode pads 4c and 4c corresponding to each of the Au bumps 9 and 9 (C = D).

In addition, the Au bumps 9 of the silicon chip 6C are arranged so that the pitches of the Au bumps 9 adjacent to each other are the same, and the electrode pads 4c to which these Au bumps 9 are connected are also adjacent electrodes. It is arrange | positioned so that the pitch of the pad 4c may become all the same. Therefore, when the amount of deviation between the arbitrary Au bumps 9 and the corresponding electrode pads 4c is 0, the amount of deviation between the other Au bumps 9 and the corresponding electrode pads 4c is all zero. .

The electrode pad 4c to which the Au bumps 9 of the silicon chip 6C are connected is wider than the width of the electrode pad 4a to which the Au bumps 9 of the silicon chip 6A are connected. . For example, when the width of the electrode pads 4a and 4b is set to 20 µm to 25 µm, the width of the electrode pad 4c is 50 µm to 55 µm. The positional relationship between the Au bumps 9 arranged on the three other sides of the silicon chip 6C and the electrode pads 4c corresponding thereto is also similar to the above.

Although not shown, the relative positional relationship between the Au bump 9 of the silicon chip 6B on which the DRAM is formed and the electrode pad 4b corresponding thereto is the same as that of the silicon chip 6A shown in FIG. . That is, the total pitch of the Au bumps 9 arranged in a line along each side of the silicon chip 6B is wider than the total pitch of the corresponding electrode pad 4b. In addition, the pitch of the adjacent Au bumps 9 of each of the silicon chips 6B is larger than the pitch of the corresponding electrode pads 4b of the module substrate 2.

Specifically, the electrode pad 4b at the position deviating from the electrode pad 4b at the starting point, namely the module substrate, with the electrode pad 4b at the position closest to the center of the module substrate 2 as a starting point. As for the electrode pad 4b located closer to the periphery of (2), the positional shift with respect to the Au bump 9 is larger.

As described above, in the present embodiment, when the silicon chips 6A and 6B having a narrow pitch of the Au bumps 9 are mounted on the module substrate 2, the total pitch of the corresponding electrode pads 4 is changed to the Au bumps 9. Narrower than the total pitch. In this case, the total pitch of the electrode pads 4 is the difference in thermal expansion coefficient between the silicon constituting the chip and the resin material constituting the module substrate 2 (epoxy resin in this embodiment), and the total pitch of the Au bumps 9. It calculates based on parameters, such as the position of the electrode pad 4 on the module substrate 2, the heat processing temperature at the time of chip mounting mentioned later.

8 is a plan view of the main surface of the module substrate 2 showing the layout of the electrode pads 4 (4a, 4b, 4c) to which the Au bumps 9 of the silicon chips 6A, 6B, and 6C are connected. In addition, illustration of the electrode pad 4 to which the passive element is connected, and the wiring 3 which connects the electrode pad 4 to each other is abbreviate | omitted.

As illustrated, the electrode pad 4c to which the Au bumps 9 of the silicon chip 6C are connected has a wide pitch and a wide pitch because the Au bumps 9 have a wide pitch. In contrast, the electrode pads 4a and 4b to which the Au bumps 9 of the silicon chips 6A and 6B are connected have a narrow pitch and a narrow pitch because the Au bumps 9 have a narrow pitch.

Next, a process of mounting the silicon chips 6A, 6B, and 6C on the module substrate 2 will be described.

In order to mount the silicon chip 6A having a narrow pitch of the Au bumps 9 on the module substrate 2, first, as shown in FIG. 9, an anisotropic conductive film is formed on the electrode pads 4a of the module substrate 2. Bond 10a. The anisotropic conductive film 10a is obtained by processing an uncured epoxy resin in which metal particles such as Ni (nickel) are dispersed in the form of a film. To the electrode pad 4a.

Next, as shown in FIG. 10, the silicon chip 6A is mounted on the upper surface of the anisotropic conductive film 10a. At this time, the alignment is performed so that the amount of deviation in the cross-sectional direction of Fig. 10 of the Au bump 9 and the electrode pad 4a corresponding thereto located at the center of one side of the silicon chip 6A shown in Fig. 10 becomes almost zero. Is done.

Next, by applying a pressure tool (not shown) from the upper side, a pressure of about 10 to 20 kg / cm 2 is applied to the upper surface of the silicon chip 6A, and in this state, the module substrate 2 is heated to about 180 ° C., thereby providing anisotropy. The conductive film 10a is once melted and then cured. Accordingly, as shown in FIG. 11, the gap between the silicon chip 6A and the module substrate 2 is filled with the anisotropic conductive resin 10, and the Au bumps 9 and the electrodes are formed through the metal particles in the resin. The pad 4a is electrically connected.

In addition, when the above heat treatment is performed, the silicon chip 6A and the module substrate 2 thermally expand, respectively. Therefore, the total pitch A 'of the two Au bumps 9 and 9 disposed at both ends of one side of the silicon chip 6A is widened (A'> A), and at the same time, these two Au bumps 9 and 9 ), The total pitch B 'of the two electrode pads 4a and 4a corresponding to each other is also widened (B'> B).

In this case, since the coefficient of thermal expansion of the silicon chip 6A is 3 ppm and the coefficient of thermal expansion of the module substrate 2 mainly containing an epoxy resin is about 14 ppm, the amount of variation in the dimensions of the module substrate 2 compared to the silicon chip 6A. This is big. That is, the difference between the total pitch at the time of heat treatment and the total pitch at the time of heat treatment (A'-A, B'-B) is larger than that of the silicon chip 6A. A'-A) <(B'-B)]. Therefore, when the above heat treatment is performed, the relative deviation amount from the Au bumps 9 becomes larger as compared with that before the heat treatment, as the electrode pads 4a closer to both ends of the row of electrode pads 4a.

However, as shown in FIG. 6, in this embodiment, the total pitch B of the electrode pad 4a is narrower than the total pitch A of the Au bumps 9 in advance, and the electrodes are close to both ends of the row of electrode pads 4a. Since the amount of deviation from the Au bumps 9 is increased as the pads 4a are formed, when the above heat treatment is performed, the Au bumps 9 and the corresponding electrode pads 4a approach each other as the temperature increases, and the anisotropic conductive film When the temperature at which 10a is melted and hardened is reached, the amount of deviation of both becomes almost zero in all the electrode pads 4a.

Furthermore, after performing the above heat treatment to melt and harden the anisotropic conductive film 10a, and fill the gap between the silicon chip 6A and the module substrate 2 with the anisotropic conductive resin 10, Au bumps 9 And the electrode pad 4a is sealed in the anisotropic conductive resin 10, the Au bumps 9 and the electrode pads 4a when the silicon chip 6A and the module substrate 2 shrink in the process of returning to room temperature. ) Position shift does not occur again.

In contrast, the total pitch B of the electrode pad 4a is previously matched with the total pitch A of the Au bumps 9, and the amount of deviation between the Au bumps 9 and the corresponding electrode pads 4a is changed prior to the heat treatment. In the case where 0 is set in all the electrode pads 4a, as shown in FIG. 12, the Au bumps 9 are closer to the electrode pads 4a closer to both ends of the row of electrode pads 4a when the above heat treatment is performed. The amount of deviation with and becomes large, and the contact area between them cannot be secured.

On the other hand, in order to mount the silicon chip 6C having a wide pitch of the Au bumps 9 on the module substrate 2, first, as shown in FIG. 13, anisotropy is formed on the electrode pads 4c of the module substrate 2. After attaching the conductive film 10b, the silicon chip 6C is mounted on the upper surface thereof, and the alignment is performed so that the amount of deviation of all the Au bumps 9 and the electrode pads 4c corresponding thereto is almost zero.

Next, by pressing a pressure tool (not shown) from the upper side, a pressure of about 10 to 20 kg / cm 2 is applied to the upper surface of the silicon chip 6C, and in this state, the module substrate 2 is heated to about 180 ° C. The anisotropic conductive film 10b is melted and hardened. Thus, as shown in FIG. 14, the gap between the silicon chip 6C and the module substrate 2 is filled with the anisotropic conductive resin 10, and the Au bumps 9 and the electrodes are formed through the metal particles in the resin. The pad 4c is electrically connected.                     

When the above heat treatment is performed, the module substrate 2 and the silicon chip 6C are thermally expanded, so that the total pitch C 'of the two Au bumps 9 and 9 arranged at both ends of one side of the silicon chip 6C is wide. In addition to C '> C, the total pitch D' of the two electrode pads 4c and 4c corresponding to each of these two Au bumps 9 and 9 is also widened (D '> D). At this time, since the module substrate 2 having a large coefficient of thermal expansion is more thermally expanded than the silicon chip 6C, the electrode pads 4c closer to both ends of the row of electrode pads 4c have a greater number of adjacent electrode pads 4c. The pitch becomes wider, and the amount of deviation from the Au bumps 9 becomes larger than before the heat treatment.

However, in this embodiment, since the width of the electrode pad 4c is widened in advance, even if the electrode pad 4c and the Au bump 9 are displaced by the above-described heat treatment, the contact area between the two is It is secured enough.

In addition, since the multi-chip module 1 of this embodiment mounts four silicon chips 6B on the module substrate 2 (refer FIG. 1), in the actual manufacturing process, the electrode pad of the module substrate 2 ( After attaching the anisotropic conductive film 10b on 4b), four silicon chips 6B are mounted on the upper surface thereof, and a pressing tool is simultaneously fixed on the silicon chips 6B from the upper side to fix the module substrate 2. Heat. In this case, the anisotropic conductive film 10b can also be cut to a size that covers the entire mounting regions of the four silicon chips 6B.

In addition, when the thickness of the silicon chip 6B is the same as the thickness of the silicon chip 6A, these silicon chips 6A and 6B may be packaged simultaneously. When the thickness of the silicon chips 6A and 6B is different, by mounting them in order from thin chips (that is, chips having a low mounting height), the pressing tool contacts the first chip when the pressing tool is fixed to the chip. The point can be avoided.

Although not shown, the silicon chip 6B is mounted on the module substrate 2 in the same manner as the method in which the silicon chip 6A is mounted on the module substrate 2. As described above, the silicon chip 6B having a narrow pitch of the Au bumps 9 has a total pitch of the electrode pad 4b in advance than the total pitch of the Au bumps 9 in the same manner as the silicon chip 6A. In order to make it narrow, when the heat processing for filling the gap | interval of the module board | substrate 2 with the anisotropic conductive resin 10 is performed, the amount of deviation of the Au bump 9 and the electrode pad 4b all the electrode pads 4b. ) Is almost zero.

The silicon chips 6A, 6B, and 6C are sequentially or collectively mounted on the module substrate 2 by the above-described method, and the passive element 7 is then mounted on the module substrate 2 by a known solder reflow method thereafter or before. The multichip module 1 shown in Fig. 1 is completed by mounting on the main surface of the &quot; When the heat treatment temperature for filling the anisotropic conductive resin 10 in the gap between the silicon chips 6A, 6B, 6C and the module substrate 2 is higher than the reflow temperature of the solder, the silicon chips 6A, 6B, By mounting the passive element 7 after mounting 6C, it is possible to prevent the problem that the solder is remelted in the mounting steps of the silicon chips 6A, 6B, and 6C.

As described above, in the present embodiment, when the silicon chips 6A and 6B having a narrow pitch of the Au bumps 9 are mounted on the module substrate 2, the thermal expansion of the silicon chips 6A and 6B and the module substrate 2 is performed. In consideration of the coefficient difference, the total pitch of the electrode pad 4 is made narrower than the total pitch of the Au bumps 9 in advance. This prevents misalignment between the Au bumps 9 and the electrode pads 4 during the heat treatment, thereby ensuring a contact area between the Au bumps 9 and the electrode pads 4, so that even if an expensive ceramic substrate is not used, the silicon chip The connection reliability of 6A, 6B and the module board | substrate 2 can be improved, and the multichip module 1 suitable for high density mounting can be provided at low cost.

In Example 1, a case has been described in which the silicon chip is applied to a method for manufacturing a multichip module in which a silicon chip is mounted on a module substrate through an anisotropic conductive resin. The present invention can also be widely applied to semiconductor devices that perform high temperature heat treatment in flip chip mounting processes.

For example, as Example 2, FIG. 15 electrically connects the several Au bumps 9 formed in the main surface (element formation surface) of the silicon chip 6D to the electrode pad 4 of the wiring board 12. As shown in FIG. The underfill resin (sealing resin) 13 is filled in the gap between the silicon chip 6D and the wiring board 12. The underfill resin 13 is comprised by the epoxy-type thermosetting resin containing the silica filler, for example, and the wiring board 12 is comprised by the glass fiber impregnated epoxy resin, for example.

In order to fill the underfill resin 13 in the gap between the silicon chip 6D and the wiring board 12, first, an Au bump 9 of the silicon chip 6D is electrically connected to the electrode pad 4 of the wiring board 12. After supplying the liquid underfill resin 13 to the outer circumference of the silicon chip 6D by using a dispenser or the like, the wiring board 12 was about 70 ° C. in order to increase the fluidity of the underfill resin 13. Warm up. As a result, the underfill resin 13 is filled in the gap between the silicon chip 6D and the wiring board 12 by capillary action. Then, the wiring board 12 is heat-processed about 150 degreeC, and the underfill resin 13 is hardened.                     

The underfill resin 13 filled in the gap between the silicon chip 6D and the wiring board 12 may be a liquid, and may be a film obtained by processing an uncured epoxy resin into a film. In this case, similarly to the first embodiment, a film cut to the same size as that of the silicon chip 6D is interposed between the Au bumps 9 and the electrode pads 4, and in this state, the wiring board 12 is placed. The film is melted and cured by heating to about 150 ° C.

Also in the semiconductor device as described above, when the pitch of the Au bumps 9 formed in the silicon chip 6D is narrow, and the pitch and the width of the electrode pads 4 of the wiring board 12 are thus narrowed, silicon In consideration of the difference in thermal expansion coefficient between the chip 6D and the wiring board 12, the total pitch of the electrode pad 4 is made narrower than the total pitch of the Au bumps 9 in advance. This prevents misalignment between the Au bumps 9 and the electrode pads 4 during the heat treatment, thereby ensuring a contact area between the Au bumps 9 and the silicon pads 6D even when an expensive ceramic substrate is not used. ) And the wiring board 12 can be improved in connection reliability.

16 is a semiconductor device in which several solder bumps 14 formed on the main surface (element formation surface) of the silicon chip 6E are electrically connected to the electrode pads 4 of the wiring board 15. As shown in FIG. 17, the solder bump 14 is comprised with the solder material of comparatively low melting | fusing point, such as Sn-Ag alloy (melting point 221 degreeC) containing 3 weight% Ag, for example. In addition, the wiring board 13 is comprised by glass fiber impregnation epoxy resin, for example.

In the semiconductor device as described above, since the high-temperature heat treatment is performed in the step of reflowing the solder bumps 14, the pitch of the solder bumps 14 formed on the silicon chip 6E is narrow, whereby the wiring board ( In the case where the pitch and width of the electrode pads 4 of 15 are narrowed, the total pitch of the electrode pads 4 is solder bump in advance in consideration of the difference in thermal expansion coefficient between the silicon chip 6E and the wiring board 15. I make it narrower than the total pitch of (14). This prevents misalignment between the solder bumps 14 and the electrode pads 4 during the heat treatment, thereby ensuring a contact area between the silicon bumps 6E even when an expensive ceramic substrate is not used. ) And the wiring board 15 can be improved in connection reliability. After the heat treatment, in order to prevent distortion or damage of the solder bumps 14 caused by cooling of the semiconductor device, an underfill resin (sealing resin) is filled in the gap between the silicon chip 6E and the wiring board 15. It is good to fix. At this time, in order to reduce distortion and internal stress generated in the solder bumps 14, the wiring board 15 or the semiconductor chip at a temperature higher than normal temperature, more preferably at a temperature close to the heat treatment temperature in the reflow process. It is preferable to harden the underfill resin in the state which heated 6E, and to fix the silicon chip 6E and the wiring board 15. FIG. Specifically, as the curing step of the underfill resin, a thermosetting or thermoplastic resin is used at a temperature higher than the temperature at the time of operation of the semiconductor element and at a lower temperature than the melting point of the solder bumps. The silicon chip 6E and the wiring board 15 It is preferable to harden | cure at the clearance gap of.

As mentioned above, although the invention made by this inventor was demonstrated concretely based on the said Example, this invention is not limited to the said Example, Of course, it can change variously in the range which does not deviate from the summary.

The present invention is applicable to a multichip module in which lead in which Au bumps are connected to the electrode pads through an anisotropic conductive resin, and chips in which Au bumps or solder bumps are directly connected to the electrode pads are mixed and mounted on the same wiring board. It may be. In addition, the above-described method can be applied to a package for mounting a single chip on a wiring board.

The present invention can be applied not only to flip chip mounting of a chip having a narrow pitch of bump electrodes on a wiring board but also to flip chip mounting of a large area chip on a wiring board. Since the chip of the large area has a large total pitch of the bump electrodes and a total pitch of the electrode pads on the wiring board side, even when the bump electrodes have a relatively large pitch, the bump electrodes and the electrodes during the heat treatment performed in the chip mounting process. The amount of deviation of the pad increases. Therefore, by applying this invention, the connection reliability of a bump electrode and an electrode pad can be improved.

Among the inventions disclosed in the present specification, the effects obtained representatively will be briefly described as follows.

According to the present invention, when mounting a chip having a narrow pitch of bump electrodes on a wiring board, the total pitch of the electrode pad is made narrower than the total pitch of the bump electrodes in consideration of the difference in thermal expansion coefficient between the chip and the wiring board. The displacement of the bump electrodes and the electrode pads due to the thermal expansion coefficient difference between the chip and the wiring board can be prevented, and the contact area between them can be secured.

Claims (34)

delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete (a) providing a semiconductor chip having a main surface on which a plurality of bump electrodes are formed; (b) providing a wiring board having a main surface on which a plurality of electrodes are formed; (c) arranging the semiconductor chip on the main surface of the wiring board such that the plurality of bump electrodes of the semiconductor chip and the plurality of electrodes of the wiring board are individually connected in a mutually opposite relationship, and the wiring Curing the resin by a heat treatment between the main surface of the substrate and the main surface of the semiconductor chip to fix the wiring substrate and the semiconductor chip with the cured resin, The wiring substrate has a coefficient of thermal expansion that is greater than that of the semiconductor chip, and in step (b) before the step (c), the plurality of bump electrodes of the semiconductor chip have the wiring at a temperature lower than the heat treatment temperature. A method of manufacturing a semiconductor device having pitches wider than corresponding pitches of the plurality of electrodes of the substrate. The method of claim 27, And a plurality of bump electrodes formed on the main surface of the semiconductor chip are made of Au. The method of claim 27, And the plurality of bump electrodes are arranged around the main surface of the semiconductor chip. The method of claim 27, In the step (c), applying a compression pressure to the semiconductor chip by a pressing tool. (a) providing a semiconductor chip having a main surface on which a plurality of bump electrodes are formed; (b) providing a wiring board having a main surface on which a plurality of electrodes are formed; (c) arranging the semiconductor chip on the main surface of the wiring board such that the plurality of bump electrodes of the semiconductor chip and the plurality of electrodes of the wiring board are connected to each other separately so as to be individually connected to each other. Curing the resin by a heat treatment between a main surface and a main surface of the semiconductor chip to fix the wiring board and the semiconductor chip with the cured resin, The wiring board has a thermal expansion coefficient larger than that of the semiconductor chip, and the distance from one end to the other end of the array of the plurality of electrodes formed on the main surface of the wiring board provided in step (b) is A method for manufacturing a semiconductor device, the distance of which is smaller than the distance from one end to the other end of the array of bump electrodes formed on the main surface of the semiconductor chip provided in the step (a). The method of claim 31, wherein And a plurality of bump electrodes formed on the main surface of the semiconductor chip are made of Au. The method of claim 31, wherein And the plurality of bump electrodes are arranged around the main surface of the semiconductor chip. The method of claim 31, wherein In the step (c), applying a compression pressure to the semiconductor chip by a pressing tool.

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